Hot Carrier Mobility Dynamics Unravel Competing Subpicosecond Processes in Lead Halide Perovskites

Burgos‐Caminal, Andrés; Moreno-Naranjo, Juan Manuel; Willauer, Aurélien R.; Paraecattil, Arun Aby; Ajdarzadeh, Ahmad; Moser, Jacques-E.

doi:10.1021/acs.jpcc.0c08492

Cited by 14 publications

(24 citation statements)

References 46 publications

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“…A similar argument is valid to exclude charge-carrier cooling as the potential source of the early time reduction in photoconductivity: given that higher-lying bands in metal-halide perovskites have lower curvature (higher effective mass), charge-carrier relaxation into the more curved (lower effective mass) band extrema should lead to a rise in charge-carrier mobility and thus photoconductivity. This has been observed in excess-energy dependent OPTP spectroscopy in conventional metal-halide perovskites , but is the opposite to what is observed here for Cu 2 AgBiI 6 . Given this, we argue that the thermally activated hopping mobility μ loc indicates the formation of small polarons or self-trapped carriers in Cu 2 AgBiI 6 , as outlined above, at the lowest point of the bandstructure. ,, …”

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confidence: 94%

Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications

et al. 2021

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Lead-free silver–bismuth semiconductors have become increasingly popular materials for optoelectronic applications, building upon the success of lead halide perovskites. In these materials, charge-lattice couplings fundamentally determine charge transport, critically affecting device performance. In this study, we investigate the optoelectronic properties of the recently discovered lead-free semiconductor Cu2AgBiI6 using temperature-dependent photoluminescence, absorption, and optical-pump terahertz-probe spectroscopy. We report ultrafast charge-carrier localization effects, evident from sharp THz photoconductivity decays occurring within a few picoseconds after excitation and a rise in intensity with decreasing temperature of long-lived, highly Stokes-shifted photoluminescence. We conclude that charge carriers in Cu2AgBiI6 are subject to strong charge-lattice coupling. However, such small polarons still exhibit mobilities in excess of 1 cm2 V–1 s–1 at room temperature because of low energetic barriers to formation and transport. Together with a low exciton binding energy of ∼29 meV and a direct band gap near 2.1 eV, these findings highlight Cu2AgBiI6 as an attractive lead-free material for photovoltaic applications.

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confidence: 94%

Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications

et al. 2021

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“…54 More recent studies have focused on the sub-ps timescale with a view to explore the carrier cooling dynamics. [57][58][59][60] Generally, these reports echo the results of the aforementioned transient absorption studies in that they show a delayed build-up of the signal for higher energy excitations. Bretschnedier et al showed that this build-up cannot be solely attributed to carrier 6 cooling, and contains an intrinsic term for polaron formation (~400 fs in the case of MAPbI3).…”

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confidence: 66%

“…The reduced mobility of the hot states may be due to an increase in their effective mass, as outlined in recent works. 60,68 However, taking the delayed response of the THz dynamics following the IR push, we suggest that this reduced mobility is instead caused by a temporary localized heating 69 of the MHP lattice, associated with the immediate vicinity of the localized charge-carrier (polaron). The small volume of this polaron leads to a high effective lattice temperature, and substantial reduction of the carrier mobility.…”

Section: Fig 2 Representative Pump-push-probe Transients (Left) Push-...mentioning

confidence: 84%

Multi-Pulse Terahertz Spectroscopy: Hot Polaron Photoconductivity Dynamics in Metal-Halide Perovskites

Zheng

Bakulin

2021

Physical Chemistry of Semiconductor Materials and Interfaces XX

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The behavior of hot carriers in metal-halide perovskites (MHPs) present a valuable foundation for understanding the details of carrier-phonon coupling in the materials as well as the prospective development of highly efficient hot carrier and carrier multiplication solar cells. Whilst the carrier population dynamics during cooling have been intensely studied, the evolution of the hot carrier properties, namely the hot carrier mobility, remain largely unexplored. To address this, we introduce a novel ultrafast visible pump -infrared push -terahertz probe spectroscopy (PPP-THz) to monitor the real-time conductivity dynamics of cooling carriers in methylammonium lead iodide. We find a decrease in mobility upon optically depositing energy into the carriers, which is typical of band-transport. Surprisingly, the conductivity recovery dynamics are incommensurate with the intraband relaxation measured by an analogous experiment with an infrared probe (PPP-IR), and exhibit a negligible dependence on the density of hot carriers. These results and the kinetic modelling reveal the importance of highly-localized lattice heating on the mobility of the hot electronic states. This collective polaron-lattice phenomenon may contribute to the unusual photophysics observed in MHPs and should be accounted for in devices that utilize hot carriers.

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“…We attribute this to charge-carrier relaxation preceding localization, when photoexcitation occurs well above the band gap. Studies of conventional metal-halide perovskites using OPTP spectroscopy have found slower rises in photoconductivity with increasing pump energy, [89,90] attributed to charge-carrier relaxation occurring within the first hundreds of femtoseconds: as relaxation to the bottom of the band takes place, the charge-carrier mobility increases because the band extrema are more highly curved, leading to a rise in photoconductivity response over the relaxation timescale. Such a pronounced rise in mobility (and thus photoconductivity) over the first few hundred femtoseconds is not observed in the silver-bismuth materials studied here, most likely because of the very flat band structure found in such materials, [6,91] which would lead to little change in mobility as carriers relax.…”

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confidence: 99%

Interplay of Structure, Charge‐Carrier Localization and Dynamics in Copper‐Silver‐Bismuth‐Halide Semiconductors

Buizza

Sansom

Wright

et al. 2021

Adv Funct Materials

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Silver-bismuth based semiconductors represent a promising new class of materials for optoelectronic applications because of their high stability, all-inorganic composition, and advantageous optoelectronic properties. In this study, charge-carrier dynamics and transport properties are investigated across five compositions along the AgBiI 4 -CuI solid solution line (stoichiometry Cu 4x (AgBi) 1−x I 4 ). The presence of a close-packed iodide sublattice is found to provide a good backbone for general semiconducting properties across all of these materials, whose optoelectronic properties are found to improve markedly with increasing copper content, which enhances photoluminescence intensity and charge-carrier transport. Photoluminescence and photoexcitation-energy-dependent terahertz photoconductivity measurements reveal that this enhanced charge-carrier transport derives from reduced cation disorder and improved electronic connectivity owing to the presence of Cu + . Further, increased Cu + content enhances the band curvature around the valence band maximum, resulting in lower charge-carrier effective masses, reduced exciton binding energies, and higher mobilities. Finally, ultrafast charge-carrier localization is observed upon pulsed photoexcitation across all compositions investigated, lowering the charge-carrier mobility and leading to Langevin-like bimolecular recombination. This process is concluded to be intrinsically linked to the presence of silver and bismuth, and strategies to tailor or mitigate the effect are proposed and discussed.

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Hot Carrier Mobility Dynamics Unravel Competing Subpicosecond Processes in Lead Halide Perovskites

Cited by 14 publications

References 46 publications

Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications

Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications

Multi-Pulse Terahertz Spectroscopy: Hot Polaron Photoconductivity Dynamics in Metal-Halide Perovskites

Interplay of Structure, Charge‐Carrier Localization and Dynamics in Copper‐Silver‐Bismuth‐Halide Semiconductors

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Hot Carrier Mobility Dynamics Unravel Competing Subpicosecond Processes in Lead Halide Perovskites

Cited by 14 publications

References 46 publications

Charge-Carrier Mobility and Localization in Semiconducting Cu2AgBiI6 for Photovoltaic Applications

Charge-Carrier Mobility and Localization in Semiconducting Cu2AgBiI6 for Photovoltaic Applications

Multi-Pulse Terahertz Spectroscopy: Hot Polaron Photoconductivity Dynamics in Metal-Halide Perovskites

Interplay of Structure, Charge‐Carrier Localization and Dynamics in Copper‐Silver‐Bismuth‐Halide Semiconductors

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Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications

Charge-Carrier Mobility and Localization in Semiconducting Cu₂AgBiI₆ for Photovoltaic Applications